ref: f5cc6fbe3a7bcf8bdb002c646ddd519014afafd2
dir: /os/boot/mpc/etherscc.c/
/* * SCCn ethernet */ #include "u.h" #include "lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "etherif.h" enum { Nrdre = 32, /* receive descriptor ring entries */ Ntdre = 4, /* transmit descriptor ring entries */ Rbsize = ETHERMAXTU+4, /* ring buffer size (+4 for CRC) */ Bufsize = (Rbsize+7)&~7, /* aligned */ }; enum { /* ether-specific Rx BD bits */ RxMiss= 1<<8, RxeLG= 1<<5, RxeNO= 1<<4, RxeSH= 1<<3, RxeCR= 1<<2, RxeOV= 1<<1, RxeCL= 1<<0, RxError= (RxeLG|RxeNO|RxeSH|RxeCR|RxeOV|RxeCL), /* various error flags */ /* ether-specific Tx BD bits */ TxPad= 1<<14, /* pad short frames */ TxTC= 1<<10, /* transmit CRC */ TxeDEF= 1<<9, TxeHB= 1<<8, TxeLC= 1<<7, TxeRL= 1<<6, TxeUN= 1<<1, TxeCSL= 1<<0, /* scce */ RXB= 1<<0, TXB= 1<<1, BSY= 1<<2, RXF= 1<<3, TXE= 1<<4, /* gsmrl */ ENR= 1<<5, ENT= 1<<4, /* port A */ RXD1= SIBIT(15), TXD1= SIBIT(14), /* port B */ RTS1= IBIT(19), /* port C */ CTS1= SIBIT(11), CD1= SIBIT(10), }; typedef struct Etherparam Etherparam; struct Etherparam { SCCparam; ulong c_pres; /* preset CRC */ ulong c_mask; /* constant mask for CRC */ ulong crcec; /* CRC error counter */ ulong alec; /* alighnment error counter */ ulong disfc; /* discard frame counter */ ushort pads; /* short frame PAD characters */ ushort ret_lim; /* retry limit threshold */ ushort ret_cnt; /* retry limit counter */ ushort mflr; /* maximum frame length reg */ ushort minflr; /* minimum frame length reg */ ushort maxd1; /* maximum DMA1 length reg */ ushort maxd2; /* maximum DMA2 length reg */ ushort maxd; /* rx max DMA */ ushort dma_cnt; /* rx dma counter */ ushort max_b; /* max bd byte count */ ushort gaddr[4]; /* group address filter */ ulong tbuf0_data0; /* save area 0 - current frm */ ulong tbuf0_data1; /* save area 1 - current frm */ ulong tbuf0_rba0; ulong tbuf0_crc; ushort tbuf0_bcnt; ushort paddr[3]; /* physical address LSB to MSB increasing */ ushort p_per; /* persistence */ ushort rfbd_ptr; /* rx first bd pointer */ ushort tfbd_ptr; /* tx first bd pointer */ ushort tlbd_ptr; /* tx last bd pointer */ ulong tbuf1_data0; /* save area 0 - next frame */ ulong tbuf1_data1; /* save area 1 - next frame */ ulong tbuf1_rba0; ulong tbuf1_crc; ushort tbuf1_bcnt; ushort tx_len; /* tx frame length counter */ ushort iaddr[4]; /* individual address filter*/ ushort boff_cnt; /* back-off counter */ ushort taddr[3]; /* temp address */ }; typedef struct { SCC* scc; int port; int cpm; BD* rdr; /* receive descriptor ring */ void* rrb; /* receive ring buffers */ int rdrx; /* index into rdr */ BD* tdr; /* transmit descriptor ring */ void* trb; /* transmit ring buffers */ int tdrx; /* index into tdr */ } Mot; static Mot mot[MaxEther]; static int sccid[] = {-1, SCC1ID, SCC2ID, SCC3ID, SCC4ID}; static int sccparam[] = {-1, SCC1P, SCC2P, SCC3P, SCC4P}; static int sccreg[] = {-1, 0xA00, 0xA20, 0xA40, 0xA60}; static int sccirq[] = {-1, 0x1E, 0x1D, 0x1C, 0x1B}; static void attach(Ctlr *ctlr) { mot[ctlr->ctlrno].scc->gsmrl |= ENR|ENT; eieio(); } static void transmit(Ctlr *ctlr) { int len; Mot *motp; Block *b; BD *tdre; motp = &mot[ctlr->ctlrno]; while(((tdre = &motp->tdr[motp->tdrx])->status & BDReady) == 0){ b = qget(ctlr->oq); if(b == 0) break; /* * Copy the packet to the transmit buffer. */ len = BLEN(b); memmove(KADDR(tdre->addr), b->rp, len); /* * Give ownership of the descriptor to the chip, increment the * software ring descriptor pointer and tell the chip to poll. */ tdre->length = len; eieio(); tdre->status = (tdre->status & BDWrap) | BDReady|TxPad|BDInt|BDLast|TxTC; eieio(); motp->scc->todr = 1<<15; /* transmit now */ eieio(); motp->tdrx = NEXT(motp->tdrx, Ntdre); freeb(b); } } static void interrupt(Ureg*, void *ap) { int len, events, status; Mot *motp; BD *rdre; Block *b; Ctlr *ctlr; ctlr = ap; motp = &mot[ctlr->ctlrno]; /* * Acknowledge all interrupts and whine about those that shouldn't * happen. */ events = motp->scc->scce; eieio(); motp->scc->scce = events; eieio(); if(events & (TXE|BSY|RXB)) print("ETHER.SCC#%d: scce = 0x%uX\n", ctlr->ctlrno, events); //print(" %ux|", events); /* * Receiver interrupt: run round the descriptor ring logging * errors and passing valid receive data up to the higher levels * until we encounter a descriptor still owned by the chip. */ if(events & (RXF|RXB) || 1){ rdre = &motp->rdr[motp->rdrx]; while(((status = rdre->status) & BDEmpty) == 0){ if(status & RxError || (status & (BDFirst|BDLast)) != (BDFirst|BDLast)){ //if(status & RxBuff) // ctlr->buffs++; if(status & (1<<2)) ctlr->crcs++; if(status & (1<<1)) ctlr->overflows++; //print("eth rx: %ux\n", status); if(status & RxError) print("~"); else if((status & BDLast) == 0) print("@"); } else{ /* * We have a packet. Read it into the next * free ring buffer, if any. */ len = rdre->length-4; if((b = iallocb(len)) != 0){ memmove(b->wp, KADDR(rdre->addr), len); b->wp += len; etheriq(ctlr, b, 1); } } /* * Finished with this descriptor, reinitialise it, * give it back to the chip, then on to the next... */ rdre->length = 0; rdre->status = (rdre->status & BDWrap) | BDEmpty | BDInt; eieio(); motp->rdrx = NEXT(motp->rdrx, Nrdre); rdre = &motp->rdr[motp->rdrx]; } } /* * Transmitter interrupt: handle anything queued for a free descriptor. */ if(events & TXB) transmit(ctlr); if(events & TXE) cpmop(RestartTx, motp->cpm, 0); } static void ringinit(Mot* motp) { int i, x; /* * Initialise the receive and transmit buffer rings. The ring * entries must be aligned on 16-byte boundaries. */ if(motp->rdr == 0) motp->rdr = bdalloc(Nrdre); if(motp->rrb == 0) motp->rrb = ialloc(Nrdre*Bufsize, 0); x = PADDR(motp->rrb); for(i = 0; i < Nrdre; i++){ motp->rdr[i].length = 0; motp->rdr[i].addr = x; motp->rdr[i].status = BDEmpty|BDInt; x += Bufsize; } motp->rdr[i-1].status |= BDWrap; motp->rdrx = 0; if(motp->tdr == 0) motp->tdr = bdalloc(Ntdre); if(motp->trb == 0) motp->trb = ialloc(Ntdre*Bufsize, 0); x = PADDR(motp->trb); for(i = 0; i < Ntdre; i++){ motp->tdr[i].addr = x; motp->tdr[i].length = 0; motp->tdr[i].status = TxPad|BDInt|BDLast|TxTC; x += Bufsize; } motp->tdr[i-1].status |= BDWrap; motp->tdrx = 0; } /* * This follows the MPC823 user guide: section16.9.23.7's initialisation sequence, * except that it sets the right bits for the MPC823ADS board when SCC2 is used, * and those for the 860/821 development board for SCC1. */ static void sccsetup(Mot *ctlr, SCC *scc, uchar *ea) { int i, rcs, tcs, w; Etherparam *p; IMM *io; i = 2*(ctlr->port-1); io = ioplock(); w = (TXD1|RXD1)<<i; /* TXDn and RXDn in port A */ io->papar |= w; /* enable TXDn and RXDn pins */ io->padir &= ~w; io->paodr &= ~w; /* not open drain */ w = (CD1|CTS1)<<i; /* CLSN and RENA: CDn and CTSn in port C */ io->pcpar &= ~w; /* enable CLSN (CTSn) and RENA (CDn) */ io->pcdir &= ~w; io->pcso |= w; iopunlock(); /* clocks and transceiver control: details depend on the board's wiring */ archetherenable(ctlr->cpm, &rcs, &tcs); sccnmsi(ctlr->port, rcs, tcs); /* connect the clocks */ p = (Etherparam*)KADDR(sccparam[ctlr->port]); memset(p, 0, sizeof(*p)); p->rfcr = 0x18; p->tfcr = 0x18; p->mrblr = Bufsize; p->rbase = PADDR(ctlr->rdr); p->tbase = PADDR(ctlr->tdr); cpmop(InitRxTx, ctlr->cpm, 0); p->c_pres = ~0; p->c_mask = 0xDEBB20E3; p->crcec = 0; p->alec = 0; p->disfc = 0; p->pads = 0x8888; p->ret_lim = 0xF; p->mflr = Rbsize; p->minflr = ETHERMINTU+4; p->maxd1 = Bufsize; p->maxd2 = Bufsize; p->p_per = 0; /* only moderate aggression */ for(i=0; i<Eaddrlen; i+=2) p->paddr[2-i/2] = (ea[i+1]<<8)|ea[i]; /* it's not the obvious byte order */ scc->psmr = (2<<10)|(5<<1); /* 32-bit CRC, ignore 22 bits before SFD */ scc->dsr = 0xd555; scc->gsmrh = 0; /* normal operation */ scc->gsmrl = (1<<28)|(4<<21)|(1<<19)|0xC; /* transmit clock invert, 48 bit preamble, repetitive 10 preamble, ethernet */ eieio(); scc->scce = ~0; /* clear all events */ eieio(); scc->sccm = TXE | RXF | TXB; /* enable interrupts */ eieio(); io = ioplock(); w = RTS1<<(ctlr->port-1); /* enable TENA pin (RTSn) */ io->pbpar |= w; io->pbdir |= w; iopunlock(); /* gsmrl enable is deferred until attach */ } /* * Prepare the SCCx ethernet for booting. */ int sccethreset(Ctlr* ctlr) { uchar ea[Eaddrlen]; Mot *motp; SCC *scc; char line[50], def[50]; /* * Since there's no EPROM, insist that the configuration entry * (see conf.c and flash.c) holds the Ethernet address. */ memset(ea, 0, Eaddrlen); if(memcmp(ea, ctlr->card.ea, Eaddrlen) == 0){ print("no preset Ether address\n"); for(;;){ strcpy(def, "00108bf12900"); /* valid MAC address to be used only for initial configuration */ if(getstr("ether MAC address", line, sizeof(line), def) < 0) return -1; if(parseether(ctlr->card.ea, line) >= 0 || ctlr->card.ea[0] == 0xFF) break; print("invalid MAC address\n"); } } scc = IOREGS(sccreg[ctlr->card.port], SCC); ctlr->card.irq = VectorCPIC+sccirq[ctlr->card.port]; motp = &mot[ctlr->ctlrno]; motp->scc = scc; motp->port = ctlr->card.port; motp->cpm = sccid[ctlr->card.port]; ringinit(motp); sccsetup(motp, scc, ctlr->card.ea); /* enable is deferred until attach */ ctlr->card.reset = sccethreset; ctlr->card.attach = attach; ctlr->card.transmit = transmit; ctlr->card.intr = interrupt; return 0; }